Custom quasi-secondary compressor models report errors

Question

Ke 2023년 8월 22일

0
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이 질문에 대한 바로 가기 링크

https://kr.mathworks.com/matlabcentral/answers/2011177-custom-quasi-secondary-compressor-models-report-errors

답변: Abhishek Chakram 2024년 2월 6일

I want to add a make-up port to the controllable mass flow element, but when I run it he gets the error: Cannot find parameter 'area_C'.And I want to be based on adjusting the position of interface C, what should I do.

component controlled_mass_flow_source

% Controlled Mass Flow Rate Source (2P)

% This block represents an ideal mechanical energy source in a two-phase

% fluid network that can maintain a controlled mass flow rate regardless of

% the pressure differential. There is no flow resistance and no heat

% exchange with the environment. The mass flow rate is set by the physical

% signal port M [kg/s]. A positive value causes fluid to flow from port A

% to port B.

nodes

A = foundation.two_phase_fluid.two_phase_fluid; % A:left

B = foundation.two_phase_fluid.two_phase_fluid; % B:right

C = foundation.two_phase_fluid.two_phase_fluid; %

end

inputs

% Mass flow rate

M = {0, 'kg/s'}; % M:left

end

parameters

power_spec = foundation.enum.power_spec.isentropic; % Power added

% 1 - isentropic

% 0 - none

area_A = {0.01, 'm^2'}; % Cross-sectional area at port A

area_B = {0.01, 'm^2'}; % Cross-sectional area at port B

area_C = {0.01, 'm^2'}; % Cross-sectional area at port C

end

% Parameter checks

equations

assert(area_A > 0)

assert(area_B > 0)

assert(area_C > 0)

end

variables (Access = protected)

mdot_A = {0, 'kg/s'}; % Mass flow rate into port A

mdot_B = {0, 'kg/s'}; % Mass flow rate into port B

mdot_C = {0, 'kg/s'}; % Mass flow rate into port C

Phi_A = {0, 'kW' }; % Energy flow rate into port A

Phi_B = {0, 'kW' }; % Energy flow rate into port B

Phi_C = {0, 'kW' }; % Energy flow rate into port C

end

branches

mdot_A : A.mdot -> *;

mdot_B : B.mdot -> *;

mdot_C : C.mdot -> *;

Phi_A : A.Phi -> *;

Phi_B : B.Phi -> *;

Phi_C : C.Phi -> *;

end

if power_spec == foundation.enum.power_spec.isentropic

variables (Access = private, ExternalAccess = none)

u_in_A = {1500, 'kJ/kg'}; % Specific internal energy for inflow at port A

u_in_B = {1500, 'kJ/kg'}; % Specific internal energy for inflow at port B

u_in_C = {1500, 'kJ/kg'}; % Specific internal energy for inflow at port C

u_out_A = {1500, 'kJ/kg'}; % Specific internal energy for outflow at port A

u_out_B = {1500, 'kJ/kg'}; % Specific internal energy for outflow at port B

u_out_C = {1500, 'kJ/kg'}; % Specific internal energy for outflow at port C

end

intermediates (Access = private, ExternalAccess = none)

% Compute change in specific entropy

[Ds_AB, ht_in_A, ht_out_B] = foundation.two_phase_fluid.sources.isentropic_relation( ...

A.p, B.p, u_in_A, u_out_B, mdot_A, area_A, area_B, ...

A.u_min, A.u_max, A.unorm_TLU, A.p_TLU, A.v_TLU, A.s_TLU, A.u_sat_liq_TLU, A.u_sat_vap_TLU);

[Ds_BA, ht_in_B, ht_out_A] = foundation.two_phase_fluid.sources.isentropic_relation( ...

B.p, A.p, u_in_B, u_out_A, mdot_B, area_B, area_A, ...

A.u_min, A.u_max, A.unorm_TLU, A.p_TLU, A.v_TLU, A.s_TLU, A.u_sat_liq_TLU, A.u_sat_vap_TLU);

end

% For logging

intermediates (Access = private)

power = if ge(M, 0), mdot_A*(ht_out_B - ht_in_A) else mdot_B*(ht_out_A - ht_in_B) end; % Power added to fluid flow

end

equations

% Isentropic relation between inflow and outflow

Ds_AB == 0;

Ds_BA == 0;

% Specific total enthalpy for outflow

ht_out_A == convection_A.ht_I;

ht_out_B == convection_B.ht_I;

end

else % power_spec == foundation.enum.power_spec.none

% For logging

intermediates (Access = private)

power = {0, 'kW'}; % Power added to fluid flow

end

equations

% Commanded mass flow rate

mdot_A == M;

% Mass balance

mdot_A +mdot_C +mdot_B == 0;

% Energy balance

Phi_A + Phi_B + Phi_C + power == 0;

% Run-time variable checks

assert(A.p >= A.p_min, message('physmod:simscape:library:two_phase_fluid:PressureMinValid', 'A'))

assert(A.p <= A.p_max, message('physmod:simscape:library:two_phase_fluid:PressureMaxValid', 'A'))

assert(A.u >= A.u_min, message('physmod:simscape:library:two_phase_fluid:InternalEnergyMinValid', 'A'))

assert(A.u <= A.u_max, message('physmod:simscape:library:two_phase_fluid:InternalEnergyMaxValid', 'A'))

assert(B.p >= B.p_min, message('physmod:simscape:library:two_phase_fluid:PressureMinValid', 'B'))

%assert(B.p <= B.p_max, message('physmod:simscape:library:two_phase_fluid:PressureMaxValid', 'B'))

assert(B.u >= B.u_min, message('physmod:simscape:library:two_phase_fluid:InternalEnergyMinValid', 'B'))

assert(B.u <= B.u_max, message('physmod:simscape:library:two_phase_fluid:InternalEnergyMaxValid', 'B'))

end

% Internal components that calculate energy convection at ports A and B

components (ExternalAccess = none)

convection_A = foundation.two_phase_fluid.port_convection(flow_area = area_A, length_scale = sqrt(4*area_A/pi));

convection_B = foundation.two_phase_fluid.port_convection(flow_area = area_B, length_scale = sqrt(4*area_B/pi));

end

connections

connect(A, convection_A.port)

connect(B, convection_B.port)

end

% Equate variables for internal components that calculate energy convection at ports A and B

equations

convection_A.mdot == mdot_A;

convection_A.Phi == Phi_A;

convection_B.mdot == mdot_B;

convection_B.Phi == Phi_B;

convection_A.ht_I == convection_B.ht_I;

end

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Answer 1

Abhishek Chakram 2024년 2월 6일

0
링크

이 답변에 대한 바로 가기 링크

https://kr.mathworks.com/matlabcentral/answers/2011177-custom-quasi-secondary-compressor-models-report-errors#answer_1403551

MATLAB Online에서 열기

Hi 柯,

It looks like you are trying to add a make-up port to a controlled mass flow source component in a Simscape language model. The error message: Cannot find parameter “area_C" suggests that there is a problem with the definition or usage of the parameter “area_C” in your model.

Here are the steps to address the issue and adjust the position of interface C:

It seems that you already have “area_C” defined in the parameters section of your component. Make sure that it is not commented out or removed accidentally.
To adjust the position of interface C, you will need to define how the mass flow rate into port C (“mdot_C”) is controlled. This could be done by creating another input similar to `M` for port C or by defining a relationship between “mdot_C” and other variables in the model.
You will need to add equations that describe the behavior of port C, like how ports A and B are described. This includes mass balance, energy balance, and any specific conditions or constraints for port C.
If port C also exchanges energy, you might need to add another internal component like “convection_C” for energy convection calculations at port C.

Here is a sample code for the same:

% Add the internal component for Port C
components (ExternalAccess = none)
    convection_C = foundation.two_phase_fluid.port_convection(flow_area = area_C, length_scale = sqrt(4*area_C/pi));
end
% Add the connection for Port C
connections
    connect(C, convection_C.port)
end
% Update the energy convection equations to include Port C
equations
    convection_C.mdot == mdot_C;
    convection_C.Phi  == Phi_C;
end
% Update the energy balance equation to include Port C
equations
    % Energy balance
    Phi_A + Phi_B + Phi_C + power == 0;
end